1. Field of the Invention
The present invention relates to a method of manufacturing a support member which acts as an atmospheric pressure resistant member of an electron beam displaying apparatus.
2. Description of the Related Art
A flat panel electron beam displaying apparatus using an electron-emitting device such as a surface conduction electron-emitting device or the like has been proposed as an image displaying apparatus capable of achieving reduced weight and reduced thickness. In the image displaying apparatus like this, a vacuum container is formed by oppositely arranging a rear plate having an electron-emitting device and a face plate having a light emitting member of emitting light in response to irradiation of electrons, and sealing the arranged rear and face plates via a frame member located on the fringe of the arranged plates. Besides, a support member called a spacer is provided between oppositely arranged substrates (i.e., the rear and face plates) so as to prevent transformation and damage of the substrate due to a difference of air pressure between the inside and the outside of the vacuum container.
Here, Japanese Patent Application Laid-Open No. H08-007811 discloses a constitution in which an electrode is provided on a support member as a means for preventing the support member from being electrified by collision of electrons emitted from an electron-emitting device.
With respect to the support member disclosed in Japanese Patent Application Laid-Open No. H08-007811, it is desired to improve uniformity of a potential distribution formed on the surface of the support member. To achieve this, it is necessary to high precisely form the electrode on the surface of the support member.
The present invention aims to provide a method of high precisely manufacturing a support member which is equipped with an electrode on the surface thereof.
The present invention is characterized by providing a method of manufacturing a support member to be used in an electron beam displaying apparatus in which an electron source for emitting electrons and an electron-irradiated member to which the electrons emitted from the electron source are irradiated are oppositely arranged via the support member, the method comprising: forming, on a surface of a base material, an electrode region of which resistance is lower than that of the base material; and forming, with use of a grinding stone having a convex portion, a concave portion on the surface of the base material by grinding a portion on the surface of the base material where the electrode region has been formed, and an electrode by grinding a part of the electrode region.
The present invention further comprises, as a preferred embodiment, transforming the base material by heat-drawing, in a longitudinal direction of the electrode, the base material on which the concave portion and the electrode have been formed.
According to the present invention, it is possible to high precisely manufacture the support member which is equipped with the electrode on the surface thereof. Therefore, in the electron beam displaying apparatus in which the support member according to the present invention is used, it is possible to prevent deviation of trajectory of electrons emitted from an electron-emitting device, and it is thus possible to perform high-quality image displaying.
Further features of the present invention will become apparent from the following description of the exemplary embodiments with reference to the attached drawings.
An electron beam displaying apparatus, in which a support member of the present invention is used, includes an FED (Field Emission Display) displaying apparatus and a displaying apparatus having surface conduction electron-emitting devices (SED). In these electron beam displaying apparatuses, since the support member is arranged between a rear plate on which electron-emitting devices are provided and a face plate on which a light emitter (for example, a phosphor) is provided, this case is a preferable form to which the support member according to the present invention is applied.
The rear plate 2 and the face plate 3 are fixed to a support frame 4 through a frit glass or the like to form an envelope 10. Since the rear plate 2 is provided for the purpose of mainly reinforcing the intensity of the electron source substrate 1, in a case that the electron source substrate 1 itself has the sufficient intensity, the rear plate 2 can be omitted. Plural electron-emitting devices 5 are arranged on the electron source substrate 1 to be wired in a passive matrix form by X-directional wirings Dx1 to Dxm and Y-directional wirings Dy1 to Dyn.
As the electron-emitting devices 5, cold cathode devices such as a surface conduction type, an FE (Field Emission) type or an MIM (Metal-Insulation-Metal) type are used. An electron beam from the above-mentioned electron source to be formed on the rear plate 2 is accelerated by the desired acceleration voltage, which is supplied to the face plate 3, and irradiated to the face plate 3. At this time, the phosphor emits light by a fact that electrons collide with the fluorescent film 7 formed on the face plate 3 to create the constitution that an image is produced on the face plate 3.
The constitution having the sufficient intensity for the atmospheric pressure is provided by setting up a support member 11 called a spacer between the face plate 3 and the rear plate 2. In this case, in upper and lower portions of the support member 11, that is, in a joint surface with the electron source and a joint surface with an electron beam-irradiated member (the fluorescent film 7 or the metal back 8), a low-resistance film (an edge-face electrode which not illustrated) used for surely supplying the potential on a surface of the support member 11 is provided. Then, a potential distribution is formed on a surface of the support member 11 by a fact that the potential to be supplied to the rear plate 2 and the face plate 3 is applied to upper and lower edges of the support member 11.
This potential distribution is formed by concave portions formed on an exposed surface of the support member 11 standing between the electron source and the electron beam-irradiated member and an electrode 11b extensionally existing in an X-directional place (refer to
A perspective view of an example of the support member 11 according to the present invention will be illustrated in
The support member 11 according to the present invention has the electrode 11b and concave portions 11c on a surface of a base material 11a as exemplified in
Usually, an insulating member is used for the base material 11a. In particular, a silica glass, a glass of decreasing a contained amount of impurity such as Na or the like, a soda lime glass and a ceramics member such as an alumina or the like are enumerated. In case of executing a heat-drawing process in the second embodiment to be described later, a glass is used. It is also possible to give electro-conductivity to these members arbitrarily. In addition, it is preferable that a coefficient of thermal expansion of the base material 11a approximates to that of the members of forming the rear plate 2 and the face plate 3.
An electrode region 12 is formed on a surface of the base material 11a. The electrode region 12, which is such a region of which the resistance is lower than that of the base material 11a, can be preferably formed by arranging an electro-conductive thin film by a photolithography method, however can be formed by dispersing metal micro-particles in the base material. In particular, metals such as Ni, Cr, Au, Mo, W, Pt, Ti, Al, Cu and Pd or alloys of these metals and print conductors constituted from metals or a metal oxide such as Pd, Ag, Au, RuO2 and Pd—Ag and the glass can be enumerated. In addition, a transparent conductor such as an In2O3—SnO2 or the like and a semiconductor material such as a polysilicon or the like are also used.
A surface of the base material 11a, on which the electrode region 12 was formed, is ground by using a grinding stone 21 having convex portions 21a and a concave portion 21b (
After grinding the base material 11a by the grinding stone 21 in this manner, the concave portions 11c and the electrode 11b are formed in a transfer region 24 of the convex portions 21a and the concave portion 21b of the grinding stone 21. At this time, the electrode 11b is uniformly ground in a whole area of the X-direction by the grinding stone 21, and since an electrode width is determined by only a difference between height of the convex portions 21a and depth of the concave portion 21b of the grinding stone 21, the electrode 11b can be formed with a uniform position and a uniform width in a whole area of an axial direction.
A boundary portion (edge portion) with the concave portions 11c of the electrode 11b can be uniformly formed with a sharp form as compared with an electrode formed by the conventional photolithography method or printing method. Therefore, accuracy of a position and a form of an electrode edge portion becomes a high level.
In case of providing the electrodes 11b and the concave portions 11c on both surfaces of the support member 11 as in
As for the support member 11 according to the present invention, the potential distribution formed along the Z-direction toward the face plate 3 from the rear plate 2 is uniformly formed for any X-directional positions and variations can be reduced as compared with a support member having an electrode according to the conventional manufacturing method. As a result, variations of electron beam irradiation positions which have been generated by the potential distribution in the X-direction on a surface of the support member 11 can be suppressed, and the electron beam in the vicinity of the support member 11 is formed on the face plate 3 as a uniform line of not having variations, and a high-quality image display can be realized.
In the above-mentioned embodiment, although the electrode 11b to be formed on a surface of the support member 11 has been described as one example, it is not limited to this case. And, the potential distribution on a surface of the support member 11 can be more uniformly formed along the X-direction by increasing the number of electrodes to become two, three or more.
Similarly, also with regard to the concave portions 11c, one or more concave portions can be formed other than the concave portion adjacent to the electrode 11b.
As the electron beam-irradiated member to be formed on the face plate 3, for example, a photoelectric conversion film other than the phosphor is used, and an image pickup electron beam displaying apparatus can be also constituted.
In addition, it is allowed that the electrode 11b is set to a floating condition without connecting to the power supply and the potential is determined by capacitive coupling depending on the potential applied to the rear plate 2 and the face plate 3, and it is also possible to perform a control by supplying the potential to the electrode 11 from an external. In the latter case, a position of the electron beam can be controlled by the potential to be supplied to the electrode, and a degree of freedom in design is widened as the electron beam displaying apparatus.
In the present embodiment, a member obtained by forming the electrode 11b and the concave portions 11c on a surface of the base material 11a in the above-mentioned first embodiment is treated as a parent material, and the support member 11 can be more precisely formed by transforming the parent material into a shape similar to that of the parent material before drawn by executing a heat-drawing process in the longitudinal direction of the electrode 11b.
In a usual electron beam displaying apparatus, the size of a support member arranged between the rear plate 2 and the face plate 3 is that the height is several mm and the length in the X-direction, although it depends on the size of a panel, is about 1200 mm if the electron beam displaying apparatus is a large 60-inch-class screen. In case of long forming an electrode zone in the X-direction on a surface of the support member having a high aspect ratio like the above-mentioned apparatus by using a photolithography method, it is very difficult to ensure linearity of edge portions of the electrode due to the residual when performing an exposure and a development.
In the present embodiment, as described in the first embodiment, since the support member is drawn in the X-direction while heating the support member after forming the electrode 11b which is parallel in the X-direction and the concave portions 11c adjacent to the electrode 11b, the forming accuracy of the electrode 11b to be formed on a surface of the support member can be further improved.
According to the present embodiment, in case of forming the electrode 11b and the concave portions 11c on the base material 11a, these portions can be fabricated with a size several tens of times of a finished product. Generally, in a drawing process, since a shape is downsized as it is and formed, a fabricating error (a roll or the like on the edge of the electrode 11b when the concave portion 11c is fabricated by a grinding stone) at a condition before executing a drawing process is also downsized as it is, and the error itself also becomes a level of one-several tenths. Therefore, an error after executing the drawing process can be reached a level of one-several tenths as compared with a case of the first embodiment.
In the support member according to the first embodiment and the second embodiment, the base material 11a is in a state of exposing in a region other than the electrode 11b. In this case, in an insulator of which the base material is made from the substance such as a glass, doubts regarding the change of potential distribution on a surface of the support member by the electrostatic charge due to the collision of electrons when the electron beam displaying apparatus is operated and the electric discharge caused by a avalanche phenomenon of the electrification charge exist.
Therefore, it is also allowed to form the support member by coating an antistatic film on a surface of the support member 11 or using a technique such as a sputtering method. As a resistance value of this antistatic film, it is desirable that the resistance value is higher than that of the electrode 11b from a viewpoint of the potential definition, and further the high resistance can be also attained by the insulator. Because, the electrostatic charge itself when electrons were irradiated to the support member can be also decreased by adjusting a secondary electron emitting coefficient of the antistatic film. Therefore, the antistatic film has a function of decreasing the electrostatic charge on a surface of the support member and a function of stably forming the potential distribution in the Z-direction of the support member 11 together with the electrode 11b on a surface of the support member.
As materials of the antistatic film, metal oxides have an excellent property, and oxides of Cr, Ni and Cu are preferable materials among the metal oxides. Other than the metal oxides, a carbon, of which the secondary electron emitting efficiency is in a low level, is a preferable material. Especially, since an amorphous carbon is in a level of a high-resistance, the resistance of the support member 11 can be easily controlled to become a desirable value.
The support member 11 illustrated in
First, the tungsten (sheet resistance: 1×105 Ω/□) was previously formed on a part of the base material 11a composed of a PD200 produced by the ASAHI Glass Co., Ltd. as an electrode region 12 by a sputtering method with a thickness of 100 nm as illustrated in FIG. 3A. Next, a surface of the base material 11a is ground by using the grinding stone 21 having the convex portions 21a and the concave portion 21b, and the electrode 11b was formed by grinding the electrode region 12 at the same time of forming the concave portions 11c. The height of the convex portions 21a of the grinding stone 21 was set to become 20 μm and the depth of the concave portion 21b was set to become 30 μm. Herewith, the electrode 11b can be formed with a state of uniform position and width in a whole area of the X-direction.
The support member 11 illustrated in
Next, the base material 11a, on which the above-mentioned concave portions 11c and the electrode 11b were formed, is heat drawn in the X-direction as the parent material 31 by a heat-drawing apparatus illustrated in
The obtained support member 11, of which the width is 1.6 mm and the thickness is 0.2 mm, was cut off by a laser of the cutoff unit 35 such that the length becomes 800 mm. The concave portions 11c of which the depth is 10 μm and the electrode 11b of which the width is 150 μm were formed on a main surface of an area 1.6 mm×800 mm of the obtained support member 11.
While the present invention has been described with reference to the exemplary embodiment, it is to be understood that the invention is not limited to the disclosed exemplary embodiment. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2008-124555, filed May 12, 2008, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
---|---|---|---|
2008-124555 | May 2008 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6222313 | Smith et al. | Apr 2001 | B1 |
6617772 | Barton et al. | Sep 2003 | B1 |
20050275335 | Hayama et al. | Dec 2005 | A1 |
20070200481 | Hayama | Aug 2007 | A1 |
20080084160 | Hayama | Apr 2008 | A1 |
20090072695 | Hiroike et al. | Mar 2009 | A1 |
Number | Date | Country |
---|---|---|
8-7811 | Jan 1996 | JP |
Number | Date | Country | |
---|---|---|---|
20090280712 A1 | Nov 2009 | US |